Point to point radio alignment system

ABSTRACT

A point to point radio alignment system is disclosed. A voltmeter positioned at the first antenna measures alignment voltage that is generated from an alignment of the first radio component positioned on the first antenna. A transceiver positioned at the first antenna receives a second alignment voltage that is measured at the second antenna and generated from an alignment of the second radio component positioned on the second antenna. A controller positioned at the first antenna simultaneously monitors the first alignment voltage as the alignment of the first radio component is adjusted and the second alignment voltage as the second radio component is adjusted. The controller simultaneously displays the first alignment voltage as the first radio component is adjusted and the second alignment voltage as the second radio component is adjusted to enable a first user to track an alignment of the first radio component and the second radio component.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a U.S. Nonprovisional Application which claims the benefit of U.S. Provisional Application No. 62/993,367 filed on Mar. 23, 2020 which is incorporated herein by reference in its entirety.

BACKGROUND Field of Disclosure

The present disclosure generally relates to radio communications and specifically to the point to point radio alignment of radio components positioned on antennas.

Related Art

Radio antennas that include radio components positioned on an antenna tower require point to point alignment with other radio antennas that also include radio components also positioned on antenna towers. The point to point alignment is necessary in order for the wireless transmission signal to travel from each radio antenna tower positioned in the wireless network. For example, a first radio component positioned on a first antenna tower is required to be aligned with a second radio component positioned on a second antenna tower in order for the first radio component positioned on the first antenna tower to transmit the wireless signal to the second radio component positioned on the second antenna tower. The misalignment of the radio components positioned on the different antenna towers may have a significant impact in the degradation of the wireless signal transmitted between the radio components.

Typically, the point to point alignment of the radio components requires a significant amount of time and resources to properly align. The radio components are significantly elevated from the ground requiring the technicians to take significant time as well as an increased risk in bodily harm in climbing to the radio components. Further, the conventional alignment process may take several hours to several days to property align thereby requiring the technicians to spend significant amount of time at the elevated heights and to repeatedly climb to the radio components before alignment is completed.

Conventional point to point alignment approaches require several technicians to operate in tandem simultaneously in order to align the radio components positioned on two different antenna towers. A first technician positioned at the elevated location of the radio component may adjust the radio component and a second technician also positioned at radio component may then identify the voltage resulting from that adjustment. The second technician may then radio to the technicians positioned at second antenna tower the voltage resulting from that adjustment. The technicians at the second antenna tower may then execute the same iterative step and radio the technicians at the first antenna tower the voltage resulting from their adjustment of the radio component. Such an iterative process may then continue for several hours to several days until the voltages resulting from the alignments of the radio components of the two antenna towers are aligned resulting in a significant increase in cost and time to properly execute the conventional point to point alignment of radio components.

BRIEF DESCRIPTION OF THE DRAWINGS/FIGURES

Embodiments of the present disclosure are described with reference to the accompanying drawings. In the drawings, like reference numerals indicate identical or functionally similar elements. Additionally, the left most digit(s) of a reference number typically identifies the drawing in which the reference number first appears.

FIG. 1 illustrates a top-elevational view of a point to point alignment configuration such that two different radio components positioned on two different antennas are aligned such that wireless communication between the two different radio components may be executed;

FIG. 2 illustrates a block diagram of a point to point alignment configuration that depicts the first point to point radio alignment system engaged with the first radio component positioned on the first antenna and the second point to point radio alignment system engaged with the second radio component positioned on the second antenna that is positioned on the roof of the building;

FIG. 3 depicts a block diagram of an example point to point radio alignment display; and

FIG. 4 depicts a block diagram of an example point to point radio alignment display.

DETAILED DESCRIPTION OF THE PRESENT DISCLOSURE

The following Detailed Description refers to accompanying drawings to illustrate exemplary embodiments consistent with the present disclosure. References in the Detailed Description to “one exemplary embodiment,” an “exemplary embodiment,” an “example exemplary embodiment,” etc., indicate the exemplary embodiment described may include a particular feature, structure, or characteristic, but every exemplary embodiment may not necessarily include the particular feature, structure, or characteristic. Moreover, such phrases are not necessarily referring to the same exemplary embodiment. Further, when a particular feature, structure, or characteristic may be described in connection with an exemplary embodiment, it is within the knowledge of those skilled in the art(s) to effect such feature, structure, or characteristic in connection with other exemplary embodiments whether or not explicitly described.

The exemplary embodiments described herein are provided for illustrative purposes, and are not limiting. Other exemplary embodiments are possible, and modifications may be made to the exemplary embodiments within the spirit and scope of the present disclosure. Therefore, the Detailed Description is not meant to limit the present disclosure. Rather, the scope of the present disclosure is defined only in accordance with the following claims and their equivalents.

Embodiments of the present disclosure may be implemented in hardware, firmware, software, or any combination thereof. Embodiments of the present disclosure may also be implemented as instructions applied by a machine-readable medium, which may be read and executed by one or more processors. A machine-readable medium may include any mechanism for storing or transmitting information in a form readable by a machine (e.g., a computing device). For example, a machine-readable medium may include read only memory (“ROM”), random access memory (“RAM”), magnetic disk storage media, optical storage media, flash memory devices, electrical optical, acoustical or other forms of propagated signals (e.g., carrier waves, infrared signals, digital signals, etc.), and others. Further firmware, software routines, and instructions may be described herein as performing certain actions. However, it should be appreciated that such descriptions are merely for convenience and that such actions in fact result from computing devices, processors, controllers, or other devices executing the firmware, software, routines, instructions, etc.

For purposes of this discussion, each of the various components discussed may be considered a module, and the term “module” shall be understood to include at least one software, firmware, and hardware (such as one or more circuit, microchip, or device, or any combination thereof), and any combination thereof. In addition, it will be understood that each module may include one, or more than one, component within an actual device, and each component that forms a part of the described module may function either cooperatively or independently from any other component forming a part of the module. Conversely, multiple modules described herein may represent a single component within an actual device. Further, components within a module may be in a single device or distributed among multiple devices in a wired or wireless manner.

The following Detailed Description of the exemplary embodiments will so fully reveal the general nature of the present disclosure that others can, by applying knowledge of those skilled in the relevant art(s), readily modify and/or adapt for various applications such exemplary embodiments, without undue experimentation, without departing from the spirit and scope of the present disclosure. Therefore, such adaptations and modifications are intended to be within the meaning and plurality of equivalents of the exemplary embodiments based upon the teaching and guidance presented herein. It is to be understood that the phraseology or terminology herein for the purpose of description and not of limitation, such that the terminology or phraseology of the present specification is to be interpreted by those skilled in the relevant art(s) in light of the teachings herein.

System Overview

FIG. 1 illustrates a top-elevational view of a point to point alignment configuration such that two different radio components positioned on two different antennas are aligned such that wireless communication between the two different radio components may be executed. A point to point alignment configuration 100 includes a first antenna 110 a. A first radio component 120 a is positioned on the first antenna 110 a and a first user 115 a is positioned by the first radio component 120 a in order to adjust the first radio component 120 a. A second antenna 110 b is positioned on the roof of a building 130. A second radio component 120 b is positioned on the second antenna 110 b and a second user 125 a is positioned by the second radio component 120 b in order to adjust the second radio component 120 b. The first radio component 120 a is positioned on a single first antenna 110 a that has a significant height and the second radio component 120 b is positioned on a single second antenna 110 b positioned on the roof of the building 120. However, the first radio component 120 a and the second radio component 120 b may be positioned on any type of antenna configuration and/or building to execute the point to point alignment of the first radio component 120 a and the second component 120 b that will be apparent to those skilled in the relevant art(s) without departing from the spirit and scope of the disclosure.

The first radio component 120 a may be aligned in a point to point alignment configuration with the second radio component 120 b in order for the first radio component 120 a and the second radio component 120 b to engage in wireless communication. The first radio component 120 a is to be aligned with the second radio component 120 b such that the alignment between the first radio component 120 a and the second radio component 120 b is within an alignment threshold of each other. The alignment threshold is the threshold that the point to point alignment of the first radio component 120 a and the second radio component 120 b is to satisfy in order for the first radio component 120 a and the second radio component 120 b to engage in wireless communication in order to adequately support the wireless network that the first radio component 120 a and the second radio component 120 b are included.

For example, the target alignment voltage that the first radio component 120 a is to be in point to point alignment with the second radio component 120 b is 4.5V. In such an example, the alignment threshold for the first radio component 120 a to engage in wireless communication with the second radio component 120 b is +−0.1V from the target alignment voltage of 4.5V. The voltage output of the first radio component 120 a is at 4.495V and the voltage output of the second radio component 120 b is at 4.505V. Since the voltage output of the first radio component 120 a is at 4.495V and the voltage output of the second radio component 120 b is at 4.505V, the alignment threshold of +−0.1V from the target alignment voltage of 4.5V is satisfied thereby enabling the first radio component 120 a and the second radio component 120 b to engage in wireless communication.

However to further the example, the voltage output of the first radio component 120 a is at 4.42V and the voltage output of the second radio component 120 b is at 4.58V. Since the voltage output of the first radio component 120 a is at 4.42V and the voltage output of the second radio component is at 4.58V, the alignment threshold of +−0.1V from the target alignment voltage 4.5V is not satisfied thereby failing to enable the first radio component 120 a and the second radio component 120 b to engage in wireless communication that is adequate to support the wireless network that the first radio component 120 a and the second radio component 120 b are included. In such an example, the first user 115 a would have to continue to adjust the first radio component 120 a and the second user 125 a would have to continue to adjust the second radio component 120 b in order to have the voltage output of the first radio component 120 a and to have the voltage output of the second radio component 120 b to be within the alignment threshold of 4.5V.

The radio frequency (RF) engineers that have designed the wireless network supported by the point to point alignment configuration 100 may determine the target alignment voltage and the alignment threshold that the first radio component 120 a is to be aligned with the second radio component 120 b. In determining the target alignment voltage and the alignment threshold, the RF engineers may determine that based on the distance the first radio component 120 a and the second radio component 120 b, the amount of bandwidth, the frequency spectrum of the bandwidth, the type of radio components, the type of antennas, the height of the radio components and so on the appropriate target alignment voltage and the alignment threshold. The appropriate target alignment voltage and the alignment threshold that the target alignment voltage of the first radio component 120 a and the second radio component 120 b are to be aligned is determined by the RF engineers based on the numerous alignment parameters incorporated by the RF engineers into the design of the wireless network supported by the first radio component 120 a and the second radio component 120 b. In doing so, the RF engineers may determine the appropriate target alignment voltage and the alignment threshold that the first radio component 120 a and the second radio component 120 b are to be aligned for the first radio component 120 a and the second radio component 120 b to engage in wireless communication that is adequate to support the wireless network that the first radio component and 120 a and the second radio component 120 b are included.

After the RF engineers have determined the appropriate target alignment voltage and the appropriate alignment threshold that the first radio component 120 a is to be aligned with the second radio component 120 b, the first radio component 120 a may be installed on the first antenna 110 a at the first location and the first radio component 120 b may be installed on the second antenna 120 b at the second location. Following the installation of the first radio component 120 a on the first antenna 110 a and the second radio component 120 b on the second antenna 110 b, the first user 115 a may climb the first antenna 110 a to take position at the first radio component 120 a and the second user 125 a may climb the second antenna 110 b to take position at the second radio component 120 b. The first user 115 a and the second user 125 a may be installers that have an expertise in aligning radio components to be within the alignment threshold of the target alignment voltage such that the corresponding radio components engage in wireless communication to support the wireless network that the radio components are included.

For example, the first radio component 120 a may be positioned on the first antenna 110 a at the first location and the second radio component 120 b may be positioned on the second antenna 110 b positioned on the roof of the building 130. The distance between the first radio component 120 a and the second radio component 120 b may be ten miles and the first radio component 120 a and the second radio component are to be aligned in a one degree of bandwidth. In doing so, the RF engineers previously determined that the target alignment voltage to align the first radio component 120 a with the second radio component 120 b is 4.5V and the alignment threshold is +−0.1V to align the first radio component 120 a with the second radio component 120 b such that the first radio component 120 a and the second radio component 120 b engage in wireless communication to support the wireless network that the first radio component 120 a and the second radio component 120 b are included based on the numerous different alignment parameters.

The first user 115 a may then install a voltmeter into a signal port of the first radio component 120 a. The signal port of the first radio component 120 a may provide a transmission signal 150 that is generated based on the wireless communication between the first radio component 120 a and the second radio component 120 b. The transmission signal 150 may be a Received Signal Strength Indicator (RSSI) that is a measurement of the power present in the transmission signal 150 as received by the first radio component 120 a from the second radio component 120 b. Different radio parameters may be associated with the first radio component 120 a and the second radio component 120 b that may include a conversion of the RSSI associated with the transmission signal 150 to a voltage value as provided by the manufacturer of the first radio component 120 a and the second radio component 120 b. Thus, the voltmeter installed into the signal port of the first radio component 120 a may provide a voltage value that corresponds to the signal strength of the transmission signal 150 received from the second radio component 120 b.

The first user 115 a may then determine the first alignment voltage of the transmission signal 150 provided by the voltmeter installed in the signal port of the first radio component 120 a. The first alignment voltage provided by the voltmeter corresponds to the current alignment of the first radio component 120 a with the second radio component 120 b based on the current signal strength of the transmission signal 150 received from the second radio component 120 b. For example, the initial first alignment voltage provided by the voltmeter is 1.1V and the 1.1V corresponds to the current signal strength of the transmission signal 150 received from the second radio component 120 b based on the current alignment of the first radio component 120 a and the second radio component 120 b.

However, in such an example, the target alignment voltage for the alignment of the first radio component 120 a and the second radio component 120 b is 4.5V as determined by the RF engineers in order for the first radio component 120 a and the second radio component 120 b to be in adequate wireless communication to support the wireless network that the first radio component 120 a and the second radio component 120 b are included. Thus, the first user 115 a is required to significantly adjust the alignment of the first radio component 120 a in order to increase the signal strength of the transmission signal 150 from the current alignment voltage of 1.1V to the target alignment voltage of 4.5V in order for the first radio component 120 a and the second radio component 120 b to be properly aligned to engage in wireless communication to support the wireless network.

The second user 125 a may then install a voltmeter into a signal port of the second radio component 120 b. The signal port of the second radio component 120 b may provide a transmission signal 150 that is generated based on the wireless communication between the first radio component 120 a and the second radio component 120 b. Thus, the voltmeter installed into the signal port of the second radio component 120 b may provide a second alignment voltage that corresponds to the signal strength of the transmission signal 150 received from the first radio component 120 b. The second user 125 a may then determine the second alignment voltage of the transmission signal 150 provided by the voltmeter installed in the signal port of the second radio component 120 b. The second alignment voltage provided by the voltmeter corresponds to the current alignment of the second radio component 120 b with the first radio component 120 a based on the current signal strength of the transmission signal 150 received from the first radio component 120 a. For example, the initial first alignment voltage provided by the voltmeter is 0.5V and the 0.5V corresponds to the current signal strength of the transmission signal 150 received from the first radio component 120 a based on the current alignment of the first radio component 120 a and the second radio component 120 b. Thus, the second user 125 a is required to significantly adjust the alignment of the second radio component 120 b in order to increase the signal strength of the transmission signal 150 from the current second alignment voltage of 0.5V to the target alignment voltage of 4.5V in order for the first radio component 120 a and the second radio component 120 b to be properly aligned to engage in wireless communication to support the wireless network.

In order for the first user 115 a to align the first radio component 120 a with the second radio component 120 b to increase the current first alignment voltage of 1.1V to 5.0V for the transmission signal 150, the first user 115 a may manually adjust the first radio component 120 a such that the physical direction that the first radio component 120 a is oriented changes. For example, the first user 115 a may manually adjust a specific alignment bolt positioned on the first radio component 120 a with a wrench in order to adjust the physical direction that the first radio component 120 a is oriented to change with the goal to adjust that physical direction to be closer aligned with the second radio component 120 b. The second user 125 a may attempt to align the second radio component 120 b in a similar manner.

Conventionally, the first user 115 a may be simply using a conventional voltmeter that is installed into the signal port of the first radio component 120 a. Typically, the first user 115 a may be accompanied by a first user 115 b that is also positioned at the first radio component 120 a on the first antenna 110 a that is typically significantly elevated from the ground. The first user 115 a may examine the first alignment voltage provided by the conventional voltmeter as the first user 115 b adjusts the alignment bolt associated with the first radio component 120 a with the wrench in an attempt to align the first radio component 120 a with the second radio component 120 b. An additional two users may then be positioned on the ground at the base of the first antenna 110 a for safety purposes requiring a total of four users to be positioned at the first antenna 110 a in the conventional approach of adjusting the first radio component 120 a to be aligned with the second radio component 120 b.

Conventionally, the second user 125 a may be simply using a conventional voltmeter that is installed into the signal port of the second radio component 120 a. Typically, the second user 125 a may be accompanied by a second user 125 b that is also positioned at the second radio component 120 b on the second antenna 110 b as positioned on the roof of the building 130 that is typically significantly elevated from the ground. The second user 125 a may examine the first alignment voltage provided by the conventional voltmeter as the second user 125 b adjusts the alignment bolt associated with the second radio component 120 b with the wrench in an attempt to align the second radio component 120 b with the first radio component 120 a. An additional two users may then be positioned on the ground at the base of the second antenna 110 b for safety purposes requiring a total of four users to be positioned at the second antenna 110 b in the conventional approach of adjusting the second radio component 120 b to be aligned with the first radio component 120 a.

Returning to the first user 115 a and the first user 115 b positioned at the first radio component 120 a on the first antenna 110 a in the conventional approach, the first user 115 b may adjust the alignment of the first radio component 120 b via a minor turn of the alignment bolt associated with the first radio component 120 b in an attempt to further align the first radio component 120 a with the second radio component 120 b. In doing so, the first alignment voltage associated with the transmission signal 150 received from the second radio component 120 b after the first user 115 b adjusts the alignment bolt associated with the first radio component 120 a with a minor turn via a wrench may then be instantaneously displayed by the conventional voltmeter. For example, the first user 115 a may determine that the first alignment voltage displayed by the conventional voltmeter following the turn of the alignment bolt associated with the first radio component 120 a changes from 1.1V to 1.6V. In doing so, the adjustment of the alignment bolt associated with the first radio component 120 a by the first user 115 b via the wrench may for the time being move the first radio component 120 a into closer alignment with the second radio component 120 b based on the second alignment voltage of the transmission signal 150 provided by the signal port of the first radio component 120 a increasing from 1.1V to 1.6V and is thereby closer to the target alignment voltage of 4.5V.

Conventionally, the first user 115 a may then radio to the second user 125 a positioned at the second radio component 120 b on the second antenna 110 b on the roof of the building 130 that the current first alignment voltage displayed by the conventional voltmeter installed into the signal port of the first radio component 120 a is 1.6V. The second user 125 b may then vocalize to the second user 125 a that the current target alignment voltage displayed by the conventional voltmeter installed into the signal port of the first radio component 120 b is 1.6V and that the second alignment voltage currently displayed by the conventional voltmeter installed in the signal port of the second radio component 120 b is 0.8V. The second user 125 a may then adjust the alignment bolt associated with the second radio component 120 b via a minor turn with a wrench in an attempt to further align the second radio component 120 b with the first radio component 120 a.

In doing so, the first alignment voltage associated with the transmission signal 150 received from the first radio component 120 a after the second user 125 b adjusts the alignment bolt associated with the second radio component 120 b with a minor turn via the wrench may then be instantaneously displayed by the conventional voltmeter. For example, the second user 125 a may determine that the second alignment voltage displayed by the conventional voltmeter following the turn of the alignment bolt associated with the second radio component 120 a changes from 0.8V to −1.6V. In doing so, the adjustment of the alignment bolt associated with the second radio component 120 b by the second user 125 b via the wrench may for the time being moved the second radio component 120 b into being further out of alignment with the first radio component 120 a based on the second alignment voltage of the transmission signal 150 provided by the signal port of the second radio component 120 b decreasing from 0.8V to −1.6V and is thereby further from the target alignment voltage of 4.5V.

The conventional iterative process discussed in the above example where the first user 115 a, 115 b adjusts the alignment bolt associated with the first radio component 120 a and then observe the instantaneous display current first alignment voltage by the conventional voltmeter and then radios that current first alignment voltage to the second user 125 a, 125 b and the second user repeats the process and may continue for hours and even days. The conventional iterative process is to continue until the first alignment voltage displayed by the conventional voltmeter that is installed into the signal port of the first radio component 120 a is within the alignment threshold of +−0.5V of the target alignment voltage of 4.5V and the second alignment voltage displayed by the conventional voltmeter that is installed into the signal port of the second radio component 120 b is within the alignment threshold of +−0.5V of the target alignment voltage of 4.5V. In doing so, the alignment of the first radio component 120 a and the second radio component 120 b may be sufficient to establish wireless communication to adequately support the wireless network that the first radio component 120 a and the second radio component 120 b are included.

However, the conventional iterative process may continue for hours and even days due to the non-historical and instantaneous feedback provided by the conventional voltmeter. As the first user 115 b adjusts the alignment bolt associated with the first radio component 120 a with the wrench, the feedback provided to the first user 115 b is limited to the instantaneous first alignment voltage displayed by the conventional voltmeter to the first user 115 a in reaction to the adjustment of the alignment bolt associated with the first radio component 120 a. The conventional voltmeter fails to provide any type of historical feedback to the first user 115 b as to the previous first alignment voltages that resulted from previous adjustments of the alignment bolt associated with the first radio component 120 a as adjusted with the wrench by the first user 115 a. The first user 115 b out of skill and experience must simply rely upon the type of adjustment that the first user 115 a made to the alignment bolt associated with the first radio component 120 a to determine the impact such an adjustment made on the first alignment voltage displayed by the conventional voltmeter without any historical knowledge of how previous adjustments impacted the first alignment voltage displayed by the conventional voltmeter.

In compounding the conventional iterative process, the second user 125 b is also adjusting the alignment bolt associated with the second radio component 120 b with the wrench in tandem with the first user 115 b adjusting the first radio component 120 a. As the second user 125 b adjusts the alignment bolt associated with the second radio component 120 b, such an adjustment may deviate significantly from the progress that the first user 115 b accomplished with the adjustment of the first radio component 120 b. As with the first user 115 b, the conventional voltmeter not only fails to provide any type of historical feedback to the second user 125 b as to the previous second alignment voltages that resulted from previous adjustments of the alignment bolt associated with the second radio component 120 b but also fails to provide any type of real-time feedback as well as historical feedback as to the second alignment voltage associated with the first radio component 120 a. The second user 115 b out of skill and experience must not only simply rely on instantaneous second alignment voltage displayed by the conventional voltmeter installed into the signal port of the second radio component 120 b but also must simply rely on the instantaneous value of the first radio component 120 a as radioed by the first user 115 a. Such lack of historical feedback and/or real-time feedback as to the second alignment voltages of the first radio component 120 a relative to the adjustment of the second radio component 120 b continues to compound the conventional iterative process of aligning the first radio component 120 a with the second radio component 120 b thereby significantly increasing the cost of the alignment.

Rather than being limited to an instantaneous and non-historical display of the current alignment voltage of the radio component as well as not having any type of feedback from the current alignment voltage of the corresponding radio component, point to point alignment system 140(a-b) may provide to the first user 115 a and the second user 125 a an instantaneous display of the current first alignment voltage of the first radio component 120 a as well as a historical display of past first alignment voltages as well as the instantaneous display of the current second alignment voltage of the second radio component 120 b as well as a historical display of past second alignment voltages of the second radio component 120 b. Point to point alignment system 140(a-b) may provide the appropriate feedback to the first user 115 a and the second user 125 a such that the first user 115 a may easily view the instantaneous display of the current first alignment voltage after adjusting the first radio component 120 a as well as view the historical display of past first alignment voltages that were generated from past adjustments of the first radio component 120 a. In doing so, the first user 115 a may have significant feedback so to the type of adjustment as well as the progress the first user 115 a is making in aligning the first radio component 120 a with the second radio component 120 b. The same type of feedback is also provided to the second user 125 a when adjusting the second radio component 120 b.

Further, the first user 115 a and the second user 125 a may have further feedback as to the instantaneous current alignment voltage of the corresponding first radio component 120 a and the second radio component 120 b as well as the historical feedback as to the past alignment voltages of the corresponding first radio component 120 a and the second radio component 120 b. In doing so, the first user 115 a may not only adjust the first radio component 120 a based on the instantaneous first current alignment voltage and the historical alignment voltages of the first radio component 120 a but may also adjust the first radio component 120 a based on the instantaneous second alignment voltage and historical second alignment voltages of the second radio component 120 b.

The significant conventional iterative process discussed above may thereby be decreased significantly as well as decreasing the amount of first users 115 a, 115 b and second users 125 a, 125 b required to conduct the alignment of the first radio component 120 a and the second radio component 120 b from four users at each site to one user at each site for simultaneous adjustment of the first radio component 120 a and the second radio component 120 b. However, a single user may be required in order to simply adjust the first radio component 120 a and then travel to the second radio component 120 b and adjust the second radio component 120 b. Regardless, the cost and the time required to align the first radio component 120 a and the second radio component 120 b to adequately establish wireless communication to support the wireless network that the first radio component 120 a and the second radio component 120 b support may be significantly decreased.

Peer to Peer Alignment

As noted above, the point to point alignment system 140(a-b) may align the first radio component 120 a that is positioned on the first antenna 110 a and the second radio component 120 b that is positioned on the second antenna 110 b to enable wireless communication between the first radio component 110 a and the second radio component 110 b. The first point to point alignment system 140 a that is positioned locally at the first radio component 120 a may determine as the first user 115 a adjusts the first radio component 120 a the first alignment voltage that is generated from the alignment of the first radio component 120 b. The first alignment voltage is adjusted when the alignment of the first radio component 120 a is adjusted. In doing so, the first alignment voltage is captured locally in real-time as the first user 115 a adjusts the first radio component 120 a. The corresponding current first alignment voltage that is generated from the adjustment of the first radio component 120 a by the first user 115 a is then transmitted to the point to point radio alignment server 160 in real-time via network 180 and is stored in the point to point radio alignment server 160.

The second point to point alignment system 140 b that is positioned locally at the second radio component 120 b may then receive the first current alignment voltage that is generated from the adjustment of the first radio component 120 a by the first user 115 a as transmitted from the point to point radio alignment server 160 via network 180 in real-time as the first alignment voltage is generated by the adjustment of the first radio component 120 a by the first user 115 a. The second user 125 a may then receive the real-time feedback as to the first alignment voltage that is currently generated by the current positioning of the first radio component 120 a. The second user 125 a may then adjust the second radio component 120 b based on the current first alignment voltage.

The second point to point alignment system 140 b may then determine as the second user 125 a adjusts the second radio component 120 b the second alignment voltage that is generated from the alignment of the second radio component 120 b. In doing so, the second alignment voltage is captured locally in real-time as the second user 125 a adjusts the second radio component 120 b. The corresponding current second alignment voltage that is generated from the adjustment of the second radio component 120 b by the second user 125 a is then transmitted to a point to point radio alignment server 160 in real-time via network 180 and is stored in the point to point radio alignment server 160. Real-time is the current alignment voltage that is generated from the current alignment of the corresponding radio component resulting from the corresponding user adjusts the corresponding radio component. A previous alignment voltage that is generated from the previous alignment of the corresponding radio component resulting from a previous adjustment of the corresponding radio component by the corresponding user is a previous alignment voltage and/or a historical alignment voltage. An alignment voltage transitions from being real-time and/or current to previous and/or historical following a subsequent adjustment by the corresponding user of the corresponding radio component that results in a subsequent change in the alignment voltage.

The point to point alignment server 160 may then store each first alignment voltage that is generated from each adjustment of the first radio component 120 a by the first user 115 a as captured and transmitted by the first point to point radio alignment system 140 a. The point to point alignment server 160 may then store each second alignment voltage that is generated from each adjustment of the second radio component 120 b by the second user 115 b as captured and transmitted by the second point to point radio alignment system 140 b. The point to point alignment server 160 may then provide via the network 180 each stored first alignment voltage to the second point to point radio alignment system 140 b such that the second user 125 a may be able to observe both the current first alignment voltage that is indicative of the current alignment of the first radio component 120 a as well as the previous and/or historical first alignment voltages as generated from previous adjustments of the first radio component 120 a by the first user 115 a.

The point to point alignment server 160 may then provide via the network 180 each stored second alignment voltage to the first point to point radio alignment system 140 a such that the first user 115 a may be able to observe both the current second alignment voltage that is indicative of the current alignment of the second radio component 120 b as well as the historical second alignment voltages as generated from previous adjustments of the second radio component 120 b by the second user 125 a. As noted above, the conventional approach of adjusting the first radio component 120 a and the second radio component 120 b such that each are adequately aligned with each other to establish wireless communication fails to have a standard and/or documented correlation between each adjustment of each corresponding alignment bolt for the first radio component 120 a and the second radio component 120 b. The conventional approach fails to have any standard and/or documented correlation between the rotations of the alignment bolt to a corresponding degree of change in the alignment of the first radio component 120 a and the second radio component 120 b. Each corresponding user 115 a and 125 a simply adjusts the alignment bolt and are limited to the instantaneous alignment voltage that is displayed by the conventional voltmeter and then radioed from the first user 115 a to the second user 125 a and/or vice versa.

Rather than relying on the conventional radioing of the instantaneous alignment voltage that is displayed by the conventional voltmeter, the transmission of the current alignment voltages in real-time for both the first radio component 120 a and the second radio component 120 b as well as the historical alignment voltages for both the first radio component 120 a and the second radio component 120 b provides a correlation of adjusting the alignment bolt for the first user 115 a and the second user 125 a. The point to point radio alignment server 160 is able to provide both the real-time current alignment voltages as well as the historical alignment voltages for both the first radio component 120 a and the second radio component 120 b such that the first user 115 a and the second user 125 a may correlate how past adjustments of the alignment bolt for the first radio component 120 a and the second radio component 120 b has impacted the resulting alignment voltages. The first user 115 a and the second user 125 a may then analyze how each adjustment of the alignment bolt impacted past alignment voltages and then may correlate how a current adjustment of the alignment bolt may impact the current alignment voltages of both the first radio component 120 a and the second radio component 120 b that are displayed to the first user 115 a and the second user 125 a in real-time. In doing so, the first user 115 a and the second user 125 a may cut down the iterative process of aligning the first radio component 120 a and the second radio component 120 b to adequately establish wireless communication to support wireless network that each are positioned significantly.

Examples of point to point alignment server 160 may include a mobile telephone, a smartphone, a workstation, a portable computing device, other computing devices such as a laptop, or a desktop computer, cluster of computers, set-top box, a product inventory checking system and/or any other suitable electronic device that will be apparent to those skilled in the relevant art(s) without departing from the spirit and scope of the invention.

In an embodiment, multiple modules may be implemented on the same point to point alignment server 160. Such a point to point alignment server 160 may include software, firmware, hardware or a combination thereof. Software may include one or more applications on an operating system. Hardware can include, but is not limited to, a processor, a memory, and/or graphical user interface display.

As shown, alignment voltages may be streamed between the first point to point radio alignment system 140 a, the second point to point radio alignment system 140 b, and the point to point alignment server 160 via network 180. Network 180 includes one or more networks, such as the Internet. In some embodiments of the present disclosure, network 180 may include one or more wide area networks (WAN) or local area networks (LAN). Network 180 may utilize one or more network technologies such as Ethernet, Fast Ethernet, Gigabit Ethernet, virtual private network (VPN), remote VPN access, a variant of IEEE 802.11 standard such as Wi-Fi, and the like. Communication over network 180 takes place using one or more network communication protocols including reliable streaming protocols such as websocket and/or transmission control protocol (TCP). Each of the first point to point radio alignment system 140 a and the second radio point to point alignment system 140 b may interface with the point to point alignment server 160 via network 180 through an application programming interface (API), web interface and/or any other type of interface that will be apparent from those skilled in the relevant art(s) without departing from the spirit and scope of the present disclosure. These examples are illustrative and not intended to limit the present disclosure.

FIG. 2 illustrates a block diagram of a point to point alignment configuration 200 that depicts the first point to point radio alignment system 140 a engaged with the first radio component 120 a positioned on the first antenna 110 a and the second point to point radio alignment system 140 b engaged with the second radio component 120 b positioned on the second antenna 110 b that is positioned on the roof of the building 130. The first point to point radio alignment system 140 a transmits the first alignment voltages to the point to point server 160 that stores the first alignment voltages in the point to point alignment database 250. The second point to point radio alignment system 140 b transmits the second alignment voltages to the point to point server 160 that stores the second alignment voltages in the point to point alignment database 250. The point to point server 160 then provides the first alignment voltages to the second point to point radio alignment system 140 b in real-time and the second alignment voltages to the first point to point radio alignment system 140 a in real-time.

The first point to point radio alignment system 140 a includes a voltmeter 210 a, a transceiver 220 a, a controller 230 a and a display 240 a. The second point to point radio alignment system 140 b includes a voltmeter 210 b, a transceiver 220 b, an controller 230 b, and a display 240 b. The point to point radio alignment configuration 200 shares many similar features with the point to point radio alignment configuration 100; therefore only the differences between the point to point radio alignment configuration 200 and the point to point radio alignment configuration 100 are to be discussed in further details.

The first point to point radio alignment system 140 a includes the voltmeter 210 a that is positioned at the first antenna 110 a and may measure the first alignment voltage that is generated from an alignment of the first radio component 120 a positioned on the first antenna 110 a. The first alignment voltage is adjusted when the alignment of the first radio component 120 a is adjusted. The first point to point radio alignment system 140 a may be installed into the port of the first radio component 120 a such that the voltmeter 210 a may measure the first alignment voltage in real-time as discussed above. The second point to point radio alignment system 140 b includes the voltmeter 210 b that is positioned at the second antenna 110 b and may measure the second alignment voltage that is generated from an alignment of the second radio component 120 a positioned on the second antenna 110 b. The second alignment voltage is adjusted when the alignment of the second radio component 120 b is adjusted. The second point to point radio alignment system 140 b may be installed into the port of the second radio component 120 b such that the voltmeter 210 b may measure the second alignment voltage in real-time as discussed above.

The first point to point radio alignment system 140 a includes the transceiver 220 a that is positioned at the first antenna 110 a and may receive the second alignment voltage that is measured at the second antenna 110 b and generated from an alignment of the second radio component 120 b positioned on the second antenna 110 b. The second point to point radio alignment system 140 b includes the transceiver 220 b that is positioned at the second antenna 110 b and may receive the first alignment that is measured at the first antenna 110 b and generated from an alignment of the first radio component 120 a positioned on the first antenna 110 a.

The first point to point radio alignment system 140 a includes the controller 230 a that is positioned at the first antenna 110 a. The controller 230 a may simultaneously monitor the first alignment voltage as the alignment of the first radio component 120 a is adjusted and the second alignment voltage as the second radio component 120 b is adjusted. The controller 230 a may simultaneously display via the display 240 a the first alignment voltage as the first radio component 120 a is adjusted and the second alignment voltage as the second radio component 120 b is adjusted to enable the first user 115 a to track an alignment of the first radio component 120 a and the second radio component 120 b via the display 240 a. The controller 230 a may determine when the first alignment voltage and the second alignment voltage are within an alignment threshold of each other. The first radio component 120 a and the second radio component 120 b are aligned to enable wireless communication when the first alignment voltage and the second alignment voltage are within the alignment threshold of each other.

The second point to point radio alignment system 140 b includes the controller 230 b that that is positioned at the second antenna 110 b. The controller 230 b may simultaneously monitor the first alignment voltage as the alignment of the first radio component 120 a is adjusted and the second alignment voltage as the second radio component 120 b is adjusted. The controller 230 a may simultaneously display via the display 240 b the first alignment voltage as the first radio component 120 a is adjusted and the second alignment voltage as the second radio component 120 b is adjusted to enable the second user 125 a to track an alignment of the first radio component 120 a and the second radio component 120 b via the display 240 b. The controller 240 b may determine when the first alignment voltage and the second alignment voltage are within an alignment threshold of each other. The first radio component 120 a and the second radio component 120 b are aligned to enable wireless communication when the first alignment voltage and the second alignment voltage are within the alignment threshold of each other.

Rather than requiring the first user 115 a to radio to the second user 125 a the instantaneous first alignment voltage as measured by the conventional voltmeter positioned at the first radio component 120 a and vice versa for the second user 125 a, the point to point alignment sever 160 may provide both the first alignment voltage and the second alignment voltage in real-time as well as the previous first alignment voltages and the second alignment voltages to the first point to point radio alignment system 140 a and the second point to point radio alignment system 140 b simultaneously. FIG. 3 depicts a block diagram of an example point to point radio alignment display 300. The example point to point radio alignment display 300 represents the first display 240 a of the first point to point radio alignment system 140 a that is displayed to the first user 115 a and the second display 240 b of the second point to point radio alignment system 140 b that is displayed to the second user 125 a.

The example point to point radio alignment display 300 depicts the listing of the real-time first alignment voltage as well as the previous first alignment voltages as depicted in the first alignment voltage listing 350 a for the first radio component 120 a as well as a historical alignment voltage graph 330 a of the first alignment voltage as depicted in the first radio component 120 a alignment voltage display 310 a. The example point to point radio alignment display 300 also depicts the real-time the first alignment voltage for the first radio component 120 b as well as the previous second alignment voltages as depicted in the second alignment voltage listing 350 b for the second radio component 120 b as well as a historical alignment voltage graph 330 b of the second alignment voltage as depicted in the second radio component 120 b alignment voltage display 310 b. The example point to point radio alignment display 300 shares many similar features with the point to point radio alignment configuration 100 and the point to point radio alignment configuration 200; therefore only the differences between the example point to point radio alignment display 300 and the point to point radio alignment configuration 100 and the point to point radio alignment configuration 200 are to be discussed in further details.

As shown in FIG. 3, the current fist alignment voltage may be depicted to the first user 115 a and the second user 125 a as shown in the first alignment voltage listing 350 a. As the first user 115 a adjusts the alignment bolt on the first radio component 120 a, the voltmeter 210 a may measure the first alignment voltage and the transceiver 220 a may transmit in real-time the first alignment voltage to the point to point alignment sever 160 and the display 340 may display to the first user 115 a the current first alignment voltage. In the example point to point alignment display 300, the display 340 depicts to the first user 115 a that the current first alignment voltage is 1.00V based on the RSSI. The point to point alignment sever 160 may then provide to the transceiver 220 b the current first alignment voltage of the first radio component 120 a as the first user 115 a adjusts the first radio component 120 a and the display 340 may display to the second user 125 a the current first alignment voltage of 1.00V in RSSI.

As the second user 125 a adjusts the alignment bolt on the second radio component 120 b, the voltmeter 210 b may measure the second alignment voltage and the transceiver 220 b may transmit in real-time the second alignment voltage to the point to point alignment server 160 and the display 340 may display to the second user 125 a the current second alignment voltage. In the example point to point alignment display 300, the display depicts to the second user 125 a that the current second alignment voltage is −1.50V based on the RSSI. The point to point alignment sever 160 may then provide to the transceiver 220 a the current second alignment voltage of the second radio component 120 b as the second user 125 a adjusts the second radio component 120 b and the display 340 may display to the first user 115 a the current second alignment voltage of −1.50V in RSSI. In doing so, both the first user 115 a and the second user 125 a may have the first alignment voltage and the second alignment voltage simultaneously displayed to the first user 115 a and the second user 125 a in real-time such that the first user 115 a and the second user 125 a may further adjust the first radio component 120 a and the second radio component 120 b, respectively, based on the real-time simultaneous display of the first alignment voltage and the second alignment voltage.

In an embodiment, the first point to point radio alignment system 140 a may provide the display 240 a that displays the example point to point alignment display in FIG. 3 to the first user 115 a in a web browser configuration. The second point to point radio alignment system 140 b may provide the display 240 b that displays the example point to point alignment display in FIG. 3 to the second user 125 a in a web browser configuration. The first transceiver 220 a may transmit the first alignment voltage in real-time to the point to point alignment server and receive the second alignment voltage in real-time via real-time two-communication in a web-socket configuration via LTE wireless communication. The second transceiver 220 b may transmit the second alignment voltage in real-time to the point to point alignment server and receive the first alignment voltage in real-time via real-time communication in a web-socket configuration via LTE wireless communication. In doing so, the first user 115 a and the second user 125 a are no longer required to radio to each other the instantaneous alignment voltages displayed by the corresponding conventional voltmeters.

However, the first and second point to point radio alignment systems 140 a, 140 b may display to the first user 115 a and the second user 125 b via any type of display configuration such that the first user 115 a and the second user 125 a may observe the alignment voltages in real-time that will be apparent to those skilled in the relevant art(s) without departing from the spirit and scope of the disclosure. Further, the first and second point to point radio alignment systems 140 a, 140 b may wirelessly communicate the alignment voltages in real-time to the point to point alignment server 160 in any wireless communication protocol such that the first user 115 a and the second user 125 a may observe the alignment voltages in real-time that will be apparent to those skilled in the relevant art(s) without departing from the spirit and scope of the disclosure. Further the first and second point to point radio alignment systems 140 a, 140 b may wirelessly communicate the alignment voltages in real-time to the point to point alignment server 160 via any wireless communication such that the first user 115 a and the second user 125 a may observe the alignment voltages in real-time that will be apparent to those skilled in the relevant art(s) without departing from the spirit and scope of the disclosure.

The controller 230 a of the first point to point radio alignment system 140 a may simultaneously identify as the first alignment voltage is adjusted from a first previous alignment voltage and as the second alignment voltage is adjusted from a second previous alignment voltage. The first alignment voltage is adjusted from the first previous alignment voltage when the first radio component 120 a is adjusted and the second alignment voltage is adjusted from the second previous alignment voltage when the second radio component 120 b is adjusted. The controller 230 a of the first point to point radio alignment system 140 a may then simultaneously display via the display 340 a first history of first alignment voltages 350 a as the first radio component 120 a is adjusted and a second history of second alignment voltages 350 b as the second radio component 120 b is adjusted to enable the first user 115 a to track a history 350(a-b) of the alignment of the first radio component 120 a and the second radio component 120 b. The first history of first alignment voltages 350 a and the second history of second alignment voltages 350 b provide feedback to the first user 115 a as to the alignment of the first radio component 120 a and the second radio component 120 b based on each adjustment. The controller 230 b of the second point to point alignment system 140 b may operate in a similar manner.

As shown in FIG. 3, the first history of first alignment voltages may be depicted to the first user 115 a and the second user 125 a as shown in the first alignment voltage listing 350 a. As the first user 115 a adjusts the alignment bolt on the first radio component 120 a, the voltmeter 210 a may measure the first alignment voltage and the transceiver 220 a may transmit in real-time the first alignment voltage to the point to point alignment server 160. The point to point alignment server 160 may then store each measured first alignment voltage as first previous alignment voltages in the point to point alignment database 250. The point to point alignment server 160 may then provide to the transceiver 220 b the stored first history of first alignment voltages of the first radio component 120 a as the first user 115 a adjusts the first radio component 120 a thereby transitioning the previous first alignment voltages generated from previous adjustments as first previous alignment voltages. The display 340 may then display to the second user 125 a the first history of first alignment voltages in the first alignment voltage listing 350 a as well as the second history of second alignment voltages in the second alignment voltage listing 350 b.

As the second user 125 a adjusts the alignment bolt on the second radio component 120 b, the voltmeter 210 b may measure the second alignment voltage and the transceiver 220 b may transmit in real-time the second alignment voltage to the point to point alignment server 160. The point to point alignment server 160 may then store each measured second alignment voltage as the second history of second alignment voltages in the point to point alignment database 250. The point to point alignment server 160 may then provide to the transceiver 220 a the stored second history of second alignment voltages of the second radio component 120 b as the second user 125 a adjusts the second radio component 120 b thereby transitioning the previous second alignment voltages generated from previous adjustments as second previous alignment voltages. The display 340 may then display to the second user 125 a the second history of second alignment voltages in the second alignment voltage listing 350 b as well as the first history of first alignment voltages in the first alignment voltage listing 350 a.

For example, the display 340 may display simultaneously to the first user 115 a via the first point to point alignment system 140 a and to the second user 125 a via the second point to point alignment system 140 b the first history of first alignment voltages as depicted in the first alignment voltage listing 350 a and the second history of second alignment voltages as depicted in the second alignment voltage listing 350 b. In such an example, the first user 115 a adjusted the first alignment voltage based on the RSSI from 1.20V to 1.50V to 2.00V to 1.50V to 1.20V with a current first alignment voltage of 1.00V. The second user 125 a adjusted the second alignment voltage based on the RSSI from 2.10V to 2.50V to 0.00V to −0.50V to −1.00V with a current second alignment voltage of −1.50V.

In such an example, the first user 115 a and the second user 125 a may have documented correlation as to the impact of each adjustment of the aligning bolt for the first radio component 120 a by the first user 115 a and the impact of each adjustment of the aligning bolt for the second radio component 120 b. Rather than simply blindly adjusting the aligning bolts without any correlation as to the impact that the adjustment of the aligning bolts have on the alignment of the first radio component 120 a with the second radio component 120 b, the first user 115 a and the second user 125 a may simultaneously view the first history of the first alignment voltages and the second history of the second alignment voltages via the display 340 to determine the correlation of the impact of each adjustment of the aligning bolts on the alignment of the first radio component 120 a and the second radio component 120 b.

In such an example, the first user 115 a and the second user 125 a may identify that the alignment of the first radio component 120 a and the second radio component 120 b is worsening. The first history of the first alignment voltages is bouncing between 1.20V and 1.00V due to the adjustment of the alignment bolt of the first radio component 120 a by the first user 115 a and the second history of the second alignment voltages is moving from 2.10V to −1.50V. Thus, the alignment of the first radio component 120 a and the second radio component 120 b is worsening and the first user 115 a and the second user 125 a may then correlate future adjustments of the alignment bolts accordingly to improve the alignment of the first radio component 120 a and the second radio component 120 b. As discussed above, in an embodiment, the first point to point radio alignment system 140 a and the second point to point radio alignment system 140 b may determine the first alignment voltages and the second alignment voltages based on the signal strength in RSSI of the transmission signal 150 between the first radio component 120 a and the second radio component 120 b. However, any type of voltage and/or signal strength measurement that may provide an indication as to the alignment of the first radio component 120 a and the second radio component 120 b may be incorporated that will be apparent to those skilled in the relevant art(s) without departing from the spirit and scope of the disclosure.

The controller 230 a of the first point to point alignment system 140 a may simultaneously display a first graph 330 a of the first history of first alignment voltages as the first radio component 120 a is adjusted and a second graph 330 b of the second history of second alignment voltages as the second radio component 120 b is adjusted to enable the first user 115 a to track the history of the alignment of the first radio component 120 a and the second radio component 120 b via the first graph 330 a and the second graph 330 b. The controller 230 b of the second point to point alignment system 140 b may operate in a similar manner.

For example, the display 340 may simultaneously display to the first user 115 a and the second user 125 a the first graph 330 a that depicts the visual graph of the first history of first alignment voltages based on the adjustment of the first radio component 120 a by the first user 115 a. In such an example, the first graph 330 a may depict the target alignment voltage 320 which is the target alignment voltage 320 determined by the RF engineer when the first alignment voltage and the second alignment voltage are within the alignment threshold of the target alignment voltage 320 that the first radio component 120 a and the second radio component 120 b are adequately aligned to establish wireless communication.

The first graph 330 a may also depict the visual graph of the first history of the first alignment voltages relative to the target alignment voltage 320. In doing so, the first user 115 a and the second user 125 a may simultaneously observe a visual graph of the first history of alignment voltages relative the target alignment voltage 320. The first user 115 a may continue to adjust the first alignment voltage of the first radio component 120 a and receive visual feedback as to the first alignment voltage relative to the target alignment voltage 320. For example, the first user 115 a may easily identify the highest first alignment voltage as well as the lowest alignment voltage from as the first user 115 a adjusts the adjustment bolt of the first radio component 120 a. The first user 115 a may then continue to observe in real-time the first alignment voltage relative to each adjustment of the alignment bolt relative to the target alignment voltage 320 such that the first user 115 a may continue to refine in real-time the adjustment of the alignment bolt such that the first graph 330 a depicts the progression of the first alignment voltage towards the target alignment voltage 320. The second graph 330 b may operate in a similar manner.

The controller 230 a of the first point to point radio alignment system 140 a may simultaneously identify for each time interval the corresponding first alignment voltage based on the alignment of the first radio component 120 a during the corresponding time interval and the corresponding second alignment voltage based on the alignment of the second radio component during the corresponding time interval. The controller 230 a may simultaneously display the first history of first alignment voltages and the second history of second alignment voltages for each corresponding time interval to enable the first user 115 a to track the history of the alignment of the first radio component 120 a and the second radio component 120 b for each corresponding time interval. The first history of alignment voltages and the second history of alignment voltages provide feedback to the first user 115 a as to the alignment of the first radio component 120 a and the second radio component 120 b based on each corresponding time interval. For example, each of the first previous alignment voltages depicted in the first alignment voltage listing 350 a and the second previous alignment voltages depicted in the second alignment voltage listing 350 b and displayed by the display 340 may be captured and displayed in a time interval of every second. The first previous alignment voltages and the second alignment voltages may be captured and displayed in any time interval that may enable first user 115 a and the second user 125 a to align the first radio component 120 a and the second radio component 120 b that will be apparent to those skilled in the relevant art(s) without departing from the spirit and scope of the disclosure.

In addition to the first user 115 a and the second user 125 a who may observe the first history of first alignment voltages and the second history of second alignment voltages to assist in the alignment of the first radio component 120 a and the second radio component 120 b, an overall administrator may also observe the first history of alignment voltages and the second history of alignment voltages as provided by the display 340 to audit whether the first user 115 a and the second user 125 a indeed adjusted the first alignment voltage and the second alignment voltage to be within the alignment threshold of the target alignment voltage 320. The overall administrator may be a supervisor of the alignment of the first radio component 120 a and the second radio component 120 b. Rather than simply relying on the first user 115 a and the second user 125 a in assuring the overall administrator that the first alignment voltage and the second alignment voltage are within the alignment threshold of the target alignment voltage 320, the overall administrator may actually verify based on the first history of alignment voltages and the second history of alignment voltages as displayed by the display 340 as to whether the first alignment voltage and the second alignment voltage are indeed within the alignment threshold of the target alignment voltage 320.

The controller 230 a of the first point to point radio alignment system 140 a may identify a model of the first radio component 120 a and correlate a RSSI value for the model of the first radio component 120 a relative to the first alignment voltage measured by the voltmeter 210 a of the first point to point radio alignment system 140 a. The controller 230 a may convert the first alignment voltage measured by the voltmeter 210 a to a corresponding RSSI value based on the correlation of the RSSI value for the model of the first radio component 120 a to the first alignment voltage. The controller 230 a may simultaneously display a first RSSI value as the first radio component 120 a is adjusted and a second RSSI value as the second radio component 120 b is adjusted to enable the first user 115 a to track the alignment of the first radio component 120 a and the second radio component 120 b. The controller 230 b of the second point to point radio alignment system 140 b may operate in a similar manner.

The controller 230 a of the first point to point radio alignment system 140 a may automatically adapt to the model of the first radio component 120 a with regard to converting the voltage measured by the voltmeter 210 a that is installed into the port of the radio component 120 a to a corresponding RSSI voltage value. Each manufacturer of each model of the first radio component 120 a may have a different conversion with regard to converting the voltage that that is measured by the voltmeter 210 a as provided by the port of the radio component 120 a to the corresponding RSSI voltage value. For example, a first manufacturer of a first radio component may have a RSSI to voltage translation that maximizes at 5V while a second manufacturer of a second radio component may have a RSSI to voltage translation that maximizes at 4V. The controller 230 a of the first point to point radio alignment system 140 a may identify the model of the first radio component 120 a and then automatically determine the RSSI to voltage translation associated with the model of the first radio component 120. Rather than requiring the first user 115 a to manually execute the conversion of the voltage measured by the voltmeter 210 based on the model of the first radio component 120 a, the controller 230 a may automatically execute the RSSI to voltage translation associated with the model of the first radio component 120 thereby triggering the display 340 to display the appropriate RSSI voltage value relative to the model of the first radio component 120 a. The controller 230 b of the second point to point radio alignment system 140 b may operate in a similar manner.

In an embodiment, a heading/tilt sensor may be positioned on the first antenna 110 a to measure a first heading RSSI value and a first tilt RSSI value that is generated from an alignment of the first radio component 120 a positioned on the first antenna 110 a. The first heading RSSI value is adjusted when a heading alignment of the first radio component 120 a is adjusted and the first tilt RSSI value is adjusted when a tilt alignment of the first radio component 120 a is adjusted. A heading/tilt sensor may be positioned on the second antenna 110 b to measure a second heading RSSI value and a first tilt RSSI value that is generated from an alignment of the second radio component 120 b positioned on the second antenna 110 b. The second RSSI value is adjusted when a heading alignment of the second radio component 120 b is adjusted and the second tilt RSSI value is adjusted when a tilt alignment of the second radio component 120 b is adjusted.

In addition to the first alignment voltage and the second alignment voltage being measured by the voltmeter 210 a and the voltmeter 210 b, heading/tilt sensors may be positioned on the first antenna 110 a and the second antenna 110 b to provide additional feedback to the first user 115 a and the second user 125 a with regard to aligning the first radio component 120 a and the second radio component 120 b. The transceiver 220 a of the first point to point radio alignment system 140 a may receive a second heading RSSI value and a second tilt RSSI value that is measured at the second antenna 110 b and generated from the alignment of the second radio component 120 b positioned on the second antenna 110 b. The transceiver 220 b of the second point to point radio alignment system 140 b may receive the first heading RSSI value and the first tilt RSSI value that is measured at the first antenna 110 a and generated from the alignment of the first radio component 120 a positioned on the first antenna 110 a.

The controller 230 a of the first point to point radio alignment system 140 a may simultaneously monitor the first heading RSSI value and the first tilt RSSI value as the first radio component is adjusted and the second heading RSSI value and the second tilt RSSI value as the second radio component is adjusted. The controller 230 a may simultaneously display the first heading RSSI value and the first tilt RSSI value is adjusted and the second heading RSSI value and the second tilt RSSI value as the second radio component is adjusted to enable the first user 115 a to track the alignment of the first radio component 120 a and the second radio component 120 b. The controller 230 a may determine when the first heading RSSI value and the first tilt RSSI value are within an alignment threshold of the second heading RSSI value and the second tilt RSSI value. The first radio component 120 a and the second radio component 120 b are aligned to enable wireless communication when the first heading RSSI value and the first tilt RSSI value are within the alignment threshold of the second heading RSSI value and the second tilt RSSI value. The controller 230 b of the second point to point radio alignment system 140 b may operate in a similar manner.

FIG. 4 depicts a block diagram of an example point to point radio alignment display 400. The example point to point radio alignment display 400 represents the first display 240 a of the first point to point radio alignment system 140 a that is displayed to the first user 115 a and the second display 240 b of the second point to point radio alignment system 140 b that is displayed to the second user 125 a. The example point to point radio alignment display 400 depicts the listing of the real-time first heading RSSI value and the first heading tilt as well as the previous first alignment voltages and the previous first tilt RSSI values as depicted in the alignment voltage listing 350 for the first radio component 120 a. This is in addition to the real-time alignment voltage as well as the previous first alignment voltages also as depicted in the alignment voltage listing 350. The example point to point alignment display 400 also depicts the listing of the real-time second heading RSSI value and the second heading tilt in the alignment voltage listing 350 for the second radio component 120 b. This is in addition to the real-time second alignment voltage as well as the previous second alignment voltages also as depicted in the alignment voltage listing 350. The alignment voltage listing also depicts the time interval that each of the alignment voltage values were measured.

The example point to point radio alignment display 400 also depicts the historical heading alignment RSSI graph 420 a and the historical tilt alignment RSSI graph 430 a as provided in the first radio component 120 a alignment voltage 410 a. The example point to point radio alignment display 400 also depicts the historical alignment voltage graph 420 b and the historical tilt alignment RSSI graph 430 b as provided in the second radio component 120 b alignment voltage 410 b. The example point to point radio alignment display 400 shares many similar features with the point to point radio alignment configuration 100, the point to point radio alignment configuration 200, and the example point to point radio alignment display 300; therefore only the differences between the example point to point radio alignment display 400 and the example point to point radio alignment display 300, the point to point radio alignment configuration 100 and the point to point radio alignment configuration 200 are to be discussed in further details.

As discussed in detail above, the adjusting of the alignment bolts based on the alignment voltage of the first radio component 120 a measured by the voltmeter 210 a installed into the signal port of the first radio component 120 a and the alignment voltage of the second radio component 120 b measured by the voltmeter 210 b installed into the signal port of the second radio component 120 b may provide feedback to the first user 115 a and the second user 125 a as to the strength of the transmission signal 150 between the first radio component 120 a and the second radio component 120 b. In addition to the feedback of the alignment voltage of the first radio component 120 a and the second radio component 120 b, the controller 230 a of the point to point radio alignment system 140 a and the controller 230 b of the point to point radio alignment system 140 b may also provide the additional feedback as to the alignment of the tilt RSSI value and the heading RSSI value for the first radio component 120 a and the second radio component 120 b.

In doing so the first user 115 a and the second user 125 a may be able to further correlate the adjustment of the tilt alignment bolt as well as the heading alignment bolt relative to the impact to the different alignment voltages for the first radio component 120 a and the second radio component 120 b. For example, the first user 115 a may adjust the tilt alignment bolt of the first radio component 120 a and then observe simultaneously in real-time that such an adjustment impacted the first alignment voltage, the first tilt RSSI value, the first heading RSSI value, the second alignment voltage, the second tilt RSSI value, and the second heading RSSI value. Such simultaneous feedback in real-time may provide the first user with further correlation as to the impact of each adjustment of the tilt alignment bolt as well as the heading alignment bolt thereby resulting in a significant decrease in time required to adequately align the first radio component 120 a and the second radio component 120 b to establish wireless communication between the first radio component 120 a and the second radio component 120 b.

Further, the additional feedback of the tilt RSSI values and the heading RSSI values may enable the first user 115 a and the second user 125 a to compartmentalize the adjusting of the first radio component 120 a and the second radio component 120 b. For example, the first user 115 a may adjust the tilt alignment bolt of the first radio component 120 a and the second user 125 a may adjust the tilt alignment bolt of the second radio component 120 b. In doing so, the first user 115 a and the second user 125 a may continue to adjust the respective tilt alignment bolts until the first tilt RSSI value for the first radio component 120 a and the second tilt RSSI value of the second radio component 120 b are within the alignment threshold of the target tilt RSSI value.

Once the first user 115 a has adjusted the first tilt RSSI value and the second user 125 a has adjusted the second tilt RSSI voltages to be within the alignment threshold of target tilt RSSI value, the first user 115 a and the second user 125 a may then move onto adjusting the respective heading alignment bolts to adjust first heading RSSI value and the second RSSI value to respectively be within the alignment threshold of the target heading RSSI value. In doing so, the first user 115 a and the first user 125 a may compartmentalize the adjusting of the respective tilt alignment bolts and the heading alignment bolts to be within the respective alignment thresholds of the target tilt RSSI value and the target heading RSSI value to thereby further decrease the time required to adequately align the first radio component 120 a with the second radio component 120 b engage in wireless communication.

In an embodiment, a Real-Time Kinematic (RTK) sensor may be positioned on the first radio component 120 a of the first antenna 110 a to measure a centimeter positioning of the first radio component 120 a of the first antenna 110 a in three-dimensional (3D) space relative to a Global Positioning Satellite (GPS). The centimeter positioning of the first radio component 120 a in 3D space may provide the height of the first radio component 120 a as well as the latitude and the longitude position of the first radio component 120 a. The centimeter positioning of the first radio component 120 a in 3D space with regard to the height, latitude, and longitude of the first radio component 120 a may be generated from an alignment of the first radio component 120 a positioned on the first antenna 110 a.

The centimeter positioning of the height, latitude, and longitude is adjusted when the first radio component 120 a is adjusted. The RTK sensor may also be positioned on the second radio component 120 b of the second antenna 110 b to provide the centimeter positioning of the height, latitude, and longitude of the second radio component 120 b. The centimeter positioning of the second radio component 120 b in 3D space with regard to height, latitude, and longitude of the second radio component 120 b may be generated from the alignment of the second radio component 120 b positioned on the second antenna 110 b. The centimeter positioning of the height, latitude, and longitude is adjusted when the second radio component 120 b is adjusted.

Further, the heading and tilt senor as well as a YAW sensor may also be positioned on the first radio component 120 a and the second radio component 120 b as discussed in detail above. In such an embodiment, the centimeter positioning of the first radio component 120 a and the second radio component 120 b based on height, longitude, and latitude may provide real-time feedback to the first user 115 a and the second user 125 a with regard to the real-time positioning of the first radio component 120 a and the second radio component 120 b. In addition, the orientation of the first radio component 120 a and the second radio component 120 b based on heading, tilt, and YAW may provide real-time feedback to the first user 115 a and the second user 125 a with regard to the real-time orientation of the first radio component 120 a and the second radio component 120 b. In doing so, the first user 115 a and the second user 125 a may receive simultaneous feedback in real-time regarding the centimeter positioning of the first radio component 120 a and the second radio component 120 b as well as the orientation of the first radio component 120 a and the second radio component 120 b thereby significantly increasing the alignment of the first radio component 120 a and the second radio component 120 b to establish wireless communication.

CONCLUSION

It is to be appreciated that the Detailed Description section, and not the Abstract section, is intended to be used to interpret the claims. The Abstract section may set forth one or more, but not all exemplary embodiments, of the present disclosure, and thus, is not intended to limit the present disclosure and the appended claims in any way.

The present disclosure has been described above with the aid of functional building blocks illustrating the implementation of specified functions and relationships thereof. The boundaries of these functional building blocks have been arbitrarily defined herein for the convenience of the description. Alternate boundaries may be defined so long as the specified functions and relationships thereof are appropriately performed.

It will be apparent to those skilled in the relevant art(s) the various changes in form and detail can be made without departing from the spirt and scope of the present disclosure. Thus the present disclosure should not be limited by any of the above-described exemplary embodiments, but should be defined only in accordance with the following claims and their equivalents. 

What is claimed is:
 1. A point to point radio alignment system that aligns a first radio component positioned on a first antenna and a second radio component positioned on a second antenna to enable wireless communication between the first radio component and the second radio component, comprising: a voltmeter positioned at the first antenna and configured to measure a first alignment voltage that is generated from an alignment of the first radio component positioned on the first antenna, wherein the first alignment voltage is adjusted when the alignment of the first radio component is adjusted; a transceiver positioned at the first antenna and configured to receive a second alignment voltage that is measured at the second antenna and generated from an alignment of the second radio component positioned on the second antenna, wherein the second alignment voltage is adjusted when the alignment of the second radio component is adjusted; a controller positioned at the first antenna and configured to: simultaneously monitor the first alignment voltage as the alignment of the first radio component is adjusted and the second alignment voltage as the second radio component is adjusted, simultaneously display the first alignment voltage as the first radio component is adjusted and the second alignment voltage as the second radio component is adjusted to enable a first user to track an alignment of the first radio component and the second radio component, and determine when the first alignment voltage and the second alignment voltage are within an alignment threshold of each other, wherein the first radio component and the second radio component are aligned to enable wireless communication when the first alignment voltage and the second alignment threshold are within the alignment threshold of each other.
 2. The point to point radio alignment system of claim 1, wherein the controller is further configured to: simultaneously identify as the first alignment voltage is adjusted from a first previous alignment voltage and as the second alignment voltage is adjusted from a second previous alignment voltage, wherein the first alignment voltage is adjusted from the first previous alignment voltage when the first radio component is adjusted and the second alignment voltage is adjusted from the second previous alignment voltage when the second radio component is adjusted; simultaneously display a first history of first alignment voltages as the first radio component is adjusted and a second history of second alignment voltages as the second radio component is adjusted to enable the first user to track a history of the alignment of the first radio component and the second radio component, wherein the first history of first alignment voltages and the second history of second alignment voltages provides feedback to the first user as to the alignment of the first radio component and the second radio component based on each adjustment.
 3. The point to point radio alignment system of claim 2, wherein the controller is further configured to simultaneously display a first graph of the first history of first alignment voltages as the first radio component is adjusted and a second graph of the second history of second alignment voltages as the second radio component is adjusted to enable the first user to track the history of the alignment of the first radio component and the second radio component via the first graph and the second graph.
 4. The point to point radio alignment system of claim 2, wherein the controller is further configured to: simultaneously identify for each time interval the corresponding first alignment voltage based on the alignment of the first radio component during the corresponding time interval and the corresponding second alignment voltage based on the alignment of the second radio component during the corresponding time interval; simultaneously display the first history of first alignment voltages and the second history of second alignment voltages for each corresponding time interval to enable the first user to track the history of the alignment of the first radio component and the second radio component for each corresponding time interval, wherein the first history of alignment voltages and the second history of alignment voltages provides feedback to the first user as to the alignment of the first radio component and the second radio component based on each corresponding time interval.
 5. The point to point radio alignment system of claim 1, wherein the transceiver is further configured to: transmit the first alignment voltage as measured at the first antenna as the first radio component positioned on the first antenna is adjusted in real-time to a point to point radio alignment server, wherein each first alignment voltage that is generated as the first radio component is adjusted in real-time is transmitted to the point to point radio alignment server; and receive the second alignment voltage as measured at the second antenna as the second radio component positioned on the second antenna is adjusted in real-time from the point to point radio alignment server, wherein each second alignment voltage that is generated as the second radio component is adjusted in real-time is received from the point to point radio alignment server.
 6. The point to point radio alignment system of claim 5, wherein the transceiver is further configured to: transmit the first alignment voltage as measured at the first antenna as the first radio component is adjusted in real-time to the point to point radio alignment server via a websocket communication channel to enable real-time wireless communication between the point to point radio alignment server and a web browser generated by the controller; and receive the second alignment voltage as measured at the second antenna as the second radio component is adjusted in real-time from the point to point radio alignment server via the websocket communication channel to enable the real-time wireless communication between the point radio alignment server and the web browser generated by the controller.
 7. The point to point radio alignment system of claim 1, wherein the controller is further configured to: identify a model of the first radio component and correlate a Received Signal Strength Indication (RSSI) value for the model of the first radio component relative to the first alignment voltage measured by the voltmeter; convert the first alignment voltage measured by the voltmeter to a corresponding RSSI value based on the correlation of the RSSI value for the model of the first radio component to the first alignment voltage; and simultaneously display a first RSSI value as the first radio component is adjusted and a second RSSI value as the second radio component is adjusted to enable the first user to track the alignment of the first radio component and the second radio component.
 8. The point to point radio alignment system of claim 7, further comprising: a heading/tilt sensor positioned at the first antenna and configured to measure a first heading RSSI value and a first tilt RSSI value that is generated from the alignment of the first radio component positioned on the first antenna, wherein the first heading RSSI value is adjusted when a heading alignment of the first radio component is adjusted and the second tilt RSSI value is adjusted when a tilt alignment of the first radio component is adjusted.
 9. The point to point radio alignment system of claim 8, wherein the transceiver is further configured to receive a second heading RSSI value and a second tilt RSSI value that is measured at the second antenna and generated from the alignment of the second radio component positioned on the second antenna, wherein the second heading RSSI value is adjusted when a heading alignment of the second radio component is adjusted and the second tilt RSSI value is adjusted when a tilt alignment of the second radio component is adjusted.
 10. The point to point radio alignment system of claim 9, wherein the controller is further configured to: simultaneously monitor the first heading RSSI value and the first tilt RSSI value as the first radio component is adjusted and the second heading RSSI value and the second tilt RSSI value as the second radio component is adjusted; simultaneously display the first heading RSSI value and first tilt RSSI value is adjusted and the second heading RSSI value and the second tilt RSSI value as the second radio component is adjusted to enable the first user to track the alignment of the first radio component and the second radio component; and determine when the first heading RSSI value and the first tilt RSSI value are within an alignment threshold of the second heading RSSI value and the second tilt RSSI value, wherein the first radio component and the second radio component are aligned to enable wireless communication when the first heading RSSI value and the first tilt RSSI value are within the alignment threshold of the second heading RSSI value and the second tilt RSSI value.
 11. A method for point to point radio alignment that aligns a first radio component positioned on a first antenna and a second radio component positioned on a second antenna to enable wireless communication between the first radio component and the second radio component, comprising: measuring, by a voltmeter positioned at the first antenna, a first alignment voltage that is generated from an alignment of the first radio component positioned on the first antenna, wherein the first alignment voltage is adjusted when the alignment of the first radio component is adjusted; receiving, by a transceiver positioned at the first antenna, a second alignment voltage that is measured at the second antenna and generated from an alignment of the second radio component positioned on the second antenna, wherein the second alignment voltage is adjusted when the alignment of the second radio component is adjusted; simultaneously monitoring, by a controller, the first alignment voltage as the alignment of the first radio component is adjusted and the second alignment voltage as the second radio component is adjusted; simultaneously displaying the first alignment voltage as the first radio component is adjusted and the second alignment voltage as the second radio component is adjusted to enable a first user to track an alignment of the first radio component and the second radio component; and determining when the first alignment voltage and the second alignment voltage are within an alignment threshold of each other, wherein the first radio component and the second radio component are aligned to enable wireless communication when the first alignment voltage and the second alignment voltage are within the alignment threshold of each other.
 12. The method of claim 11, further comprising: simultaneously identifying as the first alignment voltage is adjusted from a first previous alignment voltage and as the second alignment voltage is adjusted from a second previous alignment voltage, wherein the first alignment voltage is adjusted from the first previous alignment voltage when the first radio component is adjusted and the second alignment voltage is adjusted from the second previous alignment voltage when the second radio component is adjusted; and simultaneously displaying a first history of first alignment voltages as the first radio component is adjusted and a second history of second alignment voltages as the second radio component is adjusted to enable the first user to track a history of the alignment of the first radio component and the second radio component, wherein the first history of first alignment voltages and the second history of second alignment voltages provides feedback to the first user as to the alignment of the first radio component and the second radio component based on each adjustment.
 13. The method of claim 12, further comprising: simultaneously displaying a first graph of the first history of first alignment voltages as the first radio component is adjusted and a second graph of the second history of second alignment voltages as the second radio component is adjusted to enable the first user to track the history of the alignment of the first radio component and the second radio component via the first graph and the second graph.
 14. The method of claim 12, further comprising: simultaneously identifying for each time interval the corresponding first alignment voltage based on the alignment of the first radio component during the corresponding time interval and the corresponding second alignment voltage based on the alignment of the second radio component during the corresponding time interval; simultaneously displaying the first history of the first alignment voltages and the second history of second alignment voltages for each corresponding time interval to enable the first user to track the history of the alignment of the first radio component and the second radio component for each corresponding time interval, wherein the first history of first alignment voltages and the second history of second alignment voltages provides feedback to the first user as to the alignment of the first radio component and the second radio component based on each corresponding time interval.
 15. The method of claim 14, further comprising: transmitting the first alignment voltage as measured at the first antenna as the first radio component positioned on the first antenna is adjusted in real-time to a point to point radio alignment server, wherein each first alignment voltage that is generated as the first radio component is adjusted in real-time is transmitted to the point to point radio alignment server; and receiving the second alignment voltage as measured at the second antenna as the second radio component positioned on the second antenna is adjusted in real-time from the point to point radio alignment server, wherein each second alignment voltage that is generated as the second radio component is adjusted in real-time is received from the point to point radio alignment server.
 16. The method of claim 15, further comprising: transmitting the first alignment voltage as measured at the first antenna as the first radio component is adjusted in real-time to the point to point radio alignment server via a websocket communication channel to enable real-time wireless communication between the point to point radio alignment server and a web browser generated by the controller; and receiving the second alignment voltage as measured at the second antenna as the second radio component is adjusted in real-time from the point to point radio alignment server via the websocket communication channel to enable the real-time wireless communication between the point to point radio alignment server and the web browser generated by the controller.
 17. The method of claim 11, further comprising: identifying a model of the first radio component and correlate a Received Signal Strength Indication (RSSI) value for the model of the first radio component relative to the first alignment voltage measured by the voltmeter; converting the first alignment voltage measured by the voltmeter to a corresponding RSSI value based on the correlation of the RSSI value for the model of the first radio component to the first alignment voltage; and simultaneously displaying a first RSSI value as the first radio component is adjusted and a second RSSI value as the second radio component is adjusted to enable the first user to track the alignment of the first radio component and the second radio component.
 18. The method of claim 17, further comprising: measuring a first heading RSSI value and a first tilt RSSI value that is generated from the alignment of the first radio component positioned on the first antenna, wherein the first heading RSSI value is adjusted when a heading alignment of the first radio component is adjusted and the second tilt RSSI value is adjusted when a tilt alignment of the first radio component is adjusted.
 19. The method of claim 18, further comprising: receiving a second heading RSSI value and a second tilt RSSI value that is measured at the second antenna and generated from the alignment of the second radio component positioned on the second antenna, wherein the second heading RSSI value is adjusted when a heading alignment of the second radio component is adjusted and the second tilt RSSI value is adjusted when a tilt alignment of the second radio component is adjusted.
 20. The method of claim 19, further comprising: simultaneously monitoring the first heading RSSI value and the first tilt RSSI value as the first radio component is adjusted and the second heading RSSI value and the second RSSI tilt value as the second radio component is adjusted; simultaneously displaying the first heading RSSI value and the first tilt RSSI value as the first radio component is adjusted and the second heading RSSI value and the second tilt RSSI value as the second radio component is adjusted to enable the first user to track the alignment of the first radio component and the second radio component; and determining when the first heading RSSI value and the first tilt RSSI value are within an alignment threshold of the second heading RSSI value and the second tilt RSSI value, wherein the first radio component and the second radio component are aligned to enable wireless communication when the first heading RSSI value and the first tilt RSSI value are within the alignment threshold of the second heading RSSI value and the second tilt RSSI value. 